Antenna element self-test and monitoring

ABSTRACT

A method of testing a phased array antenna that includes a plurality of antenna element pairs, each antenna element pair of the plurality of antenna element pairs including a first antenna element and a second antenna element, the method including: for each antenna element pair of the plurality of antenna element pairs, performing a first cross element gain measurement from the first antenna element to the second antenna element of that antenna element pair; and determining whether there is a problem associated with the phased array antenna by examining the first cross element gain measurements for the plurality of antenna element pairs.

CROSS REFERENCE TO RELATED APPLICATION

This application claims the benefit of U.S. Provisional Application No.62/326,099, entitled “Antenna Element Self-Test and Monitoring,” filedApr. 22, 2016, all of which is incorporated herein by reference.

TECHNICAL FIELD

Embodiments of the present invention generally relate to testing activephased array antenna systems, and more specifically, to testing antennaelements in phased array antenna systems.

BACKGROUND

In a phased array antenna system, the array is typically a matrix ofantenna elements where each element is connected to an individualtransceiver. The transceivers are assembled and tested individually, asare the antenna elements. When the two are joined together afterindividual testing, there is a chance that one of the connections canbend, break, or present a poor RF connection for other reasons, such aspoor soldering. Once the transceivers are joined with the antennaelement array, discovering problems of this type can be difficult.

A typical antenna array system verification test requires the use of anarray test-hat or some sort of near-field sensor. Each element isactivated and verified with a field sensor measurement. There areseveral disadvantages to using such a test-hat or sensor device,including, among others: the need for a bulky, external measuring deviceof limited portability; requiring an external power source; maintainingcalibration of the sensing device; controlling the external RFenvironment; and the lack of equipment self-test.

SUMMARY

In general, in one aspect, the invention features a method of testing aphased array antenna that includes a plurality of antenna element pairs,each antenna element pair of the plurality of antenna element pairsincluding a first antenna element and a second antenna element. Themethod includes: for each antenna element pair of the plurality ofantenna element pairs, performing a first cross element gain measurementfrom the first antenna element to the second antenna element of thatantenna element pair; and determining whether there is a problemassociated with the phased array antenna by examining the first crosselement gain measurements for the plurality of antenna element pairs.

Other embodiments include one or more of the following features. Themethod also includes: for each antenna element pair of the plurality ofantenna element pairs, performing a second cross element gainmeasurement from the second antenna element to the first antenna elementof that antenna element pair, wherein determining whether there is aproblem associated with the phased array antenna also involves examiningthe second cross element gain measurements for the plurality of antennaelement pairs. Determining whether there is a problem associated withthe phased array antenna also involves, for each antenna element pairamong the plurality of antenna element pairs, comparing the first andsecond cross element gain measurements for that antenna element pair.The method also includes: for each antenna element pair of the pluralityof antenna element pairs, performing a first return loss measurement forthe first antenna element of that antenna element pair and performing asecond return loss measurement for the second antenna element of thatantenna element pair, wherein determining whether there is a problemassociated with the phased array antenna also involves examining thefirst and second return loss measurements for the plurality of antennaelement pairs. For each antenna element pair of the plurality of antennaelement pairs, performing the first cross element gain measurement fromthe first antenna element to the second antenna element of that antennaelement pair comprises measuring the power of a signal sent to the firstantenna element of that antenna element pair and measuring the powerreceived by the second antenna element of that antenna element pair.Within each antenna element pair among the plurality of antenna elementpairs the first and second antenna elements of that pair areorthogonally oriented with respect to each other, e.g. each antennaelement pair is a cross-polarized)(±45°) pair or an H—V polarized pair.

In general, in another aspect, the invention features an apparatussystem including: a phased array antenna comprising an array of antennaelements, the array of antenna elements forming a plurality of antennaelement pairs, each antenna element pair of the plurality of antennaelement pairs including a first antenna element and a second antennaelement; a plurality of transmitter circuits, each transmitter circuitsof the plurality of transmitter circuits connected to a differentcorresponding one of the antenna elements within the array of antennaelements; for each transmitter circuit among the plurality oftransmitter circuits, a bidirectional coupler connected between thattransmitter circuit and the antenna element to which that transmittercircuit is connected; a detector system for measuring a signalcharacteristic; a switching system for selectively connecting signalsfrom the bidirectional couplers for the plurality of transmittercircuits to the detector system; and a processor system. The processorsystem is programmed to use the switching system and the detector systemto perform the operations of: for each antenna element pair of theplurality of antenna element pairs, performing a first cross elementgain measurement from the first antenna element to the second antennaelement of that antenna element pair; and determining whether there is aproblem associated with the phased array antenna by examining the firstcross element gain measurements for the plurality of antenna elementpairs.

Other embodiments include one or more of the following features. Theprocessor system is further programmed to use the switching system andthe detector system to perform the operations of: for each antennaelement pair of the plurality of antenna element pairs, performing asecond cross element gain measurement from the second antenna element tothe first antenna element of that antenna element pair; and to determinewhether there is a problem associated with the phased array antenna byalso examining the second cross element gain measurements for theplurality of antenna element pairs. The processor system is furtherprogrammed to determine whether there is a problem associated with thephased array antenna by also, for each antenna element pair among theplurality of antenna element pairs, comparing the first and second crosselement gain measurements for that antenna element pair. The processorsystem is further programmed to use the switching system and thedetector system to perform the operations of: for each antenna elementpair of the plurality of antenna element pairs, performing a firstreturn loss measurement for the first antenna element of that antennaelement pair and performing a second return loss measurement for thesecond antenna element of that antenna element pair, and to determinewhether there is a problem associated with the phased array antenna alsoinvolves examining the first and second return loss measurements for theplurality of antenna element pairs. Within each antenna element pairamong the plurality of antenna element pairs, the first and secondantenna elements of that pair are orthogonally oriented with respect toeach other, e.g. each antenna element pair is a cross-polarized)(±45°)pair or an H—V polarized pair.

Still other embodiments include one or more of the following features.The apparatus further includes: an RF pilot signal source; for eachtransmitter circuit among the plurality of transmitter circuits, adirectional coupler connected to supply a signal to that transmittercircuit; and a second switching system for selectively connectingsignals from the RF pilot signal source to the directional couplers forthe plurality of transmitter circuits, and wherein the processor systemis further programmed to also use the RF pilot signal source and thesecond switching system to perform the operations of: for each antennaelement pair of the plurality of antenna element pairs, performing thefirst cross element gain measurement from the first antenna element tothe second antenna element of that antenna element pair and performingthe second cross element gain measurement from the second antennaelement to the first antenna element of that antenna element pair. Theprocessor system is further programmed to also use the RF pilot signalsource and the second switching system to perform the operations of: foreach antenna element pair of the plurality of antenna element pairs,performing the first return loss measurement for the first antennaelement of that antenna element pair and performing a second return lossmeasurement for the second antenna element of that antenna element pair.

The details of one or more embodiments of the invention are set forth inthe accompanying drawings and the description below. Other features,objects, and advantages of the invention will be apparent from thedescription and drawings, and from the claims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows the circuitry for performing return loss and cross elementgain measurements on a crossed-polarized antenna element pair within aphased array antenna.

FIG. 2 shows the circuitry for performing return loss and cross elementgain measurements on two neighboring antenna elements in a phased arrayof vertically polarized antenna elements.

FIGS. 3A and 3B show an automated procedure that is implemented by thephased array antenna system for testing the antenna elements within thearray.

FIG. 4 is an exemplary high-level block diagram showing the internalstructure of an exemplary radio head and phased array antenna.

FIG. 5 is an exemplary high-level block diagram of a Tx/Rx module suchas is shown in FIG. 4.

FIG. 6 is an exemplary block diagram of the transmitter side of anactive antenna array system showing the circuitry for only one ofmultiple transmit beams.

FIG. 7 is an exemplary block diagram of the receiver side of an activeantenna array system showing the circuitry for only one of multiplereceive beams.

In the preceding figures, like elements may be identified with likereference numbers.

DETAILED DESCRIPTION

Described below are two internal measuring methods for determiningwhether each array element is properly connected to the respectivetransceiver. Each array element typically consists of two orthogonallypolarized radiating elements, typically 90 degrees apart from eachother, as in a cross-polarized (x-pol) or horizontal-vertical polarized(HV-pol) element. Each pair of orthogonally polarized elements isself-tested by performing a return loss measurement on each individualradiating element and by performing a cross element gain measurement ineach direction.

In general, to perform a return loss measurement, a signal istransmitted to a radiating element. Part of that signal is reflectedback toward the transmitter based on the return loss or VSWR (VoltageStanding Wave Ratio) of the radiating element. (Note that a VSWRmeasurement is a form of return loss measurement as both are based onmeasuring reflected power.) With the use of a dual-directional couplerplaced at the input to the radiating element, both the transmitted andreflected signals are measured and compared. If the reflected power istoo large, then that indicates that either the connection between thetransceiver and the radiating element is damaged (e.g., improperly matedconnection) or the radiating element is damaged. This test is repeatedon the orthogonal radiating element to insure proper return loss.

To perform the cross element gain measurement, a signal is transmittedto a radiating element and the signal appearing at the orthogonalelement is measured via the reflected port of the same dual directionalcoupler used in making the return loss measurement. The measurement isrepeated in the opposite direction. The two measurements are thencompared and should be equal and within an expected range. This testinsures that the isolation between both orthogonal radiating elementsand the gain from each transceiver through to the other is within range.Improper gain or imbalance can indicate a problem with the radiatingelements or mating connections that perhaps were not indicated in thereturn loss test.

These measurements can be used not only to sense the health of the arrayelements but also to sense an improper installation due to the existenceor addition of nearby reflectors.

Also, note that the transmitted test signal used for each test can beimplemented in different ways, such as a CW (Continuous Wave) tone, aspread spectrum P-N (Pseudo-Random) signal, or by measuring andmonitoring in real-time using the signal being transmitted during normaloperation.

These tests are performed for each pair of radiating elements in thearray. For example, an array may have 48 x-pol elements. Verification ofa properly operating array would thus involve performing the testsdescribed above individually on each of the 48 element pairs.

The advantage of this type of testing is that it can be performed in thelab, in the factory, or in field service, without the need for anexternal RF test hat or sensing apparatus. These tests can also be usedto indicate the presence or sudden installation of a large reflector ata particular site, such as a nearby metal structure which couldpotentially inhibit proper cell operation.

FIG. 1 shows one implementation of a system that is capable ofperforming both the return loss and cross gain element test. It shouldbe understood that this is just one example of a number of differentways in which this can be implemented.

The described embodiment includes a cross-pole antenna arrangement 10,each element of which is electrically connected to a correspondingtransceiver, of which corresponding transmit power amplifiers 14 and 16are shown. Besides a transmit power amplifier for amplifying thetransmit signal, the transceiver also includes, among other components,a linear amplifier for amplifying the received signal, and a duplexer orswitch between the amplifiers and the antenna element (refer to FIGS.5-7 for details). In the electrical path connecting the transceiver toits corresponding antenna element, there is a bidirectional coupler(e.g. two individual unidirectional couplers arranged back-to-back or anintegrated unit that includes the back-to-back directional couplers as asingle unit) 18 and 19 with incident ports for sampling in one directionthe transmit signal sent to the antenna element and with reflected portsfor sampling in the other direction the received or reflected signalcoming from the antenna element. The couplers 18 and 19 are typicallyplaced right at or very close to the antenna element connector in orderto read the return loss of the element alone, with nothing else inbetween, for the most accurate measurement. In the case of a return lossmeasurement, placing the coupler further down the transmitter chain makethe return loss estimation of the element less accurate.

On the input side of each transmitter amplifiers 14 and 16, there arecorresponding unidirectional couplers 20 and 22 with incident ports forinjecting a test signal for transmission through the power amplifier tothe corresponding antenna element. There is also an RF pilot signalsource 24 for generating a test signal that is injected into the signalpath and an RF power detector or monitor 12 for measuring the strengthof the signal samples by the directional couplers. An RF switch matrix11 selectively couples the directional couplers 18 and 19 to the RFpower detector 12 and another RF switch matrix 21 selectively couplesthe RF pilot signal source 114 to the directional couplers 20 and 22. AμProcessor 26, which could be the μProcessor that controls the operationof the phased array or could be a separate μProcessor, controls the RFswitch matrices 11 and 21, and is also used to monitor the testmeasurements and store them in a local memory 27.

To perform the return loss measurement on transmit path A (the left pathin FIG. 1), the μProcessor 26 causes the RF switch matrix 21 to connectthe RF pilot signal to the incident port of the input directionalcoupler 20 in transmit path A. The μProcessor 26 also causes RF switchmatrix 11 to connect the RF power detector 12 to the incident port ofthe output directional coupler 18 in transmit path A and stores thevalue measured by RF power detector 12 in the memory 27. The μProcessor26 then causes the RF switch matrix 11 to switch the RF power detector12 to the reflected port of the output directional coupler 18 intransmit path A and store the value measured by the RF power detector12. The difference between the two measured values represents the returnloss of the corresponding antenna element.

The same is done for transmit path B which connects to the other antennaelement (on the right side). The return loss measurements are thencompared to the expected return loss range for a properly connected andfunctioning element to determine whether there is a problem.

To perform the cross element gain measurement from transmit path A totransmit path B, the μProcessor 26 causes the RF matrix switch 21 toconnect the RF pilot signal source 24 to the incident port of the inputdirectional coupler 20 in transmit path A. The μProcessor 26 also causesRF switch matrix 11 to connect the RF power detector 12 to the reflectedport of the output directional coupler 19 in transmit path B and storethe value measured by the RF power detector 12 in the memory 27. Toperform the cross element gain measurement from transmit path B totransmit path A, the μProcessor 26 causes the RF matrix switch 21 toconnect the RF pilot signal source 24 to the incident port of the inputdirectional coupler 22 in transmit path B. The μProcessor 26 also causesthe RF switch matrix 11 to connect the RF power detector 102 to thereflected port of the output directional coupler 18 in transmit path Aand store the value measured by the RF power detector 12 in the memory27. The absolute levels and the difference between these two measuredvalues are used to determine whether the cross element gain is balancedand within the expected tolerance.

This method will also work for a single element array, such as an arrayof vertically-polarized (V-pol) antenna elements. If there is a planararray of vertically polarized elements, a return loss measurement isperformed on each of the V-pol elements, and a cross element gain testis performed between each pair of either horizontally or verticallylocated elements. A representative system, which is shown in FIG. 2,includes an antenna element pair 10′. The components correspond to thelike-numbered components shown in FIG. 1 and perform similar or the samefunctions.

In an antenna array including elements such as those represented by FIG.2, there is likely to be no predefined grouping such as there is in thecase of the antenna array that employs cross-polarized antenna elementpairs. In that case, the antenna elements are paired in the manner thatmakes the most sense and may involve, for example, picking a nearestneighbor e.g. either in the vertical direction or the horizontaldirection. The pairing is defined in such a way that when the testing ofall pairs has taken place, then all antenna elements have been tested.

Note that performing just one of the cross element gain measurementswill yield useful information. By checking whether the cross elementgain measurement falls within a predetermined window, it will provide anindication of the health of the antenna element. However, that windowcould be very large due to the variability of the cross coupling of theelements over frequency. Performing the cross element gain measurementfor both antenna elements obviously provides considerably more usefulinformation since it provides a measure of the symmetry for the twoelements. It also checks that the transmitters on both sides areoperating within an expected range.

In a phased array antenna system that incorporates the above-describedhardware as well as control software, the antenna element tests areperformed in accordance with the procedure depicted in FIGS. 3A-B. Theprocedure is automatically initiated in some way, e.g. on a periodic,prescheduled basis, or in response to a detected change in performance,or in response to a command supplied by either a field maintenanceperson or by the base station (step 200). The procedure involvesproceeding through the phased array and testing antenna element pairsuntil all of them have been tested. In a phased array that employscross-polarized antenna elements, the pairs are naturally defined as thetwo elements within the cross-polarized antenna element.

At the start of the procedure, the system selects an initial antennaelement pair (step 202) and performs a return loss measurement on eachantenna element in that selected pair (step 204). The system thencompares the two measurements to each other to determine whether thereis any imbalance and compares each measurement to a preselectedthreshold established for identifying problems with either or both ofthe antenna elements (step 206). If any problems are detected, thesystem sets one or more flags for which element was identified as havinga potential problem (steps 208 and 210). After setting the flagsidentifying a detected problem in step 210, or if no problem wasdetected in step 208, the system stores the measurements and the resultsin local memory (step 212).

Next, the system performs a cross element gain measurement on eachantenna element in that selected pair (step 214). The system thencompares the two measurements to each other to determine whether thereis any imbalance and compares each measurement to a preselectedthreshold established for identifying problems with either or both ofthe antenna elements (step 216). If any problems are detected, thesystem sets one or more flags for which element was identified as havinga potential problem (steps 218 and 220). After setting the flagsidentifying a detected problem in step 220, or if no problem wasdetected in step 218, the system stores the measurements and the resultsin local memory (step 222).

After completing all tests for the selected pair of antenna elements,the system determines whether there remain any untested pairs (step224). If there are pairs that have not been tested, the system performsthat same set of operations for the next untested pair (step 226).

After all antenna element pairs have been tested, the system determineswhether any flags have been set for any of the tested antenna elements(228). If any flags have been set, the system reports that informationto the base station or the field investigator (step 230). After a reporthas been sent indicating that one or more antenna elements has aproblem, or if no flags have been set, indicating that the antennaelements in the array are working properly, the system ends the testsequence (step 232).

In this example the return loss measurements are performed firstfollowed by the cross element gain measurements. But that need not bethe case; other measurement and testing sequences are possible and mayeven be desirable. For example, the order can be reversed. That is, thecross gain measurements on the pair can be done first, followed by thereturn loss measurements. Or they can be performed together. When thereturn loss measurement is being performed on one antenna element, thecross gain measurement for the other element can also be performed.Similarly, there is no overriding need to compare the measurements andtest for problems in the order in which they are shown in FIGS. 3A-B.The measurement data can be collected from all of the tests on the twoelements first, and then the comparisons, tests against thresholds, anddetection of problems can be performed at the end of that sequencebefore moving on to the net antenna element pair. Or alternatively, allof the comparisons, tests against thresholds, and detection of problemscan be performed after all antenna element pairs in the array have beentested. A primary consideration is that all element pairs of interestare tested by the procedure. “All element pairs interest” may includethe entire array or a subset of the array.

The program code that operates the matrix switches, the RF powerdetector, and the RF pilot signal source and that performs the stepsdescribed above is stored in memory 27. The memory, the μProcessor, theswitches matrices, the RF power detector can be implemented centrally orcan be implemented in a distributed manner (e.g. local to the antennaelements being tested).

Power measurements can be made with either an RF power measuring module(integrated circuit) or a discrete-type circuit. Much of the circuitryfor doing this is conventional and readily available. The particularapproach that is used will depend on the accuracy required and the boardspace available.

The above-described testing method can be performed as a self-testduring start up on discrete pairs of elements in a round-robin fashion.It can also be extended to in-operation testing and to multiplesimultaneous element testing utilizing multiple discrete frequency CWtest tones, or spread spectrum PN-sequence test tones.

If the elements are tested in pairs in a round-robin fashion, then asingle fixed and common frequency CW test tone can be used for allelement tests. In order to test during operation, the elements wouldneed to be disconnected temporarily from operating in order to betested. In order to test or calibrate an element without disabling theoperating signal, a spread tone (DSSS) type-signal could be used whichcan be transmitted at a very low signal level as compared with thesignal being transmitted due to the DSSS processing gain.

FIGS. 4-7 and the following description provide details of an exemplaryactive phased array system in which the above-described test proceduresand components can be incorporated. It should be understood that thefigures illustrate just one example of many different possible ways ofimplementing an active antenna array system including analogimplementations as well as digital implementations.

Referring to FIG. 4, the phased array antenna 110 includes an array of M±45° cross-polarized antenna element pairs, each antenna element pairincluding a −45° oriented antenna element 110 a for generating a −45°polarized transmit beam and a +45° oriented antenna element 110 b forgenerating a +45° polarized transmit beam. The radio head 90 includesmultiple front-end modules (Tx/Rx modules) 100, equal in number to thenumber of antenna elements in the array, namely, 2M. There are two Tx/Rxmodules 100 for each ±45° antenna element pair, one Tx/Rx module 100connected to the −45° oriented antenna element 110 b and the other Tx/Rxmodule 100 connected to the +45° oriented antenna element 110 a. Thereis also a signal distribution network 95 that includes an IFdistribution and aggregation network and an LO signal distributionnetwork. This signal distribution network 95 delivers transmit signalsfrom the base station to the Tx/Rx modules 100, delvers received signalsfrom the Tx/Rx modules 100 to the base station, and provides coherentlocal oscillator signals to the Tx/Rx modules 100 for up-converting IFtransmit signals to RF transmit signals and for down-converting RFreceived signals to IF received signals.

FIG. 5 is a block diagram of the front-end or Tx/Rx module 100 thatconnects to a single −45° oriented antenna element 110 a of themulti-element antenna array. It includes a transmitter side and areceiver side. The transmitter side includes N up-conversion modules102, a combiner circuit 104 (e.g. a Wilkinson type combiner), and apower amplifier (PA) 106. The receiver side includes a low noiseamplifier (LNA) 112, a splitter 114 (e.g. a Wilkinson type splitter),and N down-conversion modules 116. The front-end module 100 alsoincludes a duplexer circuit 108 that couples the transmit signal fromthe PA 106 on the transmitter side to the antenna element 110 a andcouples a received signal from the antenna element 110 a to the LNA 112on the receiver side. The input of each up-conversion module 102 is forreceiving a different beam transmit signal stream BT₁ . . . BT_(n) fromthe baseband unit (not shown). And the output of each down-conversionmodule 116 is for outputting a different beam received signal stream BR₁. . . BR_(n). Typically, each beam transmit signal stream is mapped to adifferent beam that is generated by the active antenna array system andeach received signal stream corresponds to the signal received by adifferent receive beam formed by the active antenna array.

The phased array antenna system of FIG. 4 that employs the Tx/Rx module100 is capable of generating N +45° polarized beams and N −45° polarizedbeams, each of which can carry a different transmit signal.

An active antenna array system in which the up-conversion modules 102 onthe transmitter side are shown in greater detail is depicted in FIG. 6;and an active antenna array system in which the down-conversion modules116 on the receiver side are shown in greater detail is depicted in FIG.7. These transmitter side system and the receiver side system are shownseparately in FIGS. 6 and 7 to simplify the figures. But as should beapparent from FIG. 5, both transmitter side and receiver side systemsare present in the front-end. Also, it should be noted that forsimplicity FIG. 6 only shows one up-conversion module 102 and nocombiner 104 (see FIG. 5) for each antenna element that is depicted. Asshould be apparent from FIG. 5, in the complete system there aremultiple up-conversion modules 102 and a combiner 104 for each antennaelement and there are multiple down-conversion modules 116 and asplitter 114 for each antenna element.

The active antenna array system of FIG. 5 is for transmitting a signalstream over a single transmit beam that is generated by the M −45°oriented antenna elements 110 a of the antenna array (where M is aninteger that is greater 1).

Referring to FIGS. 6 and 7, there is an LO distribution network 120 fordistributing a coherent or phase-synchronized LO signal to the Mup-conversion modules 102 and the M down-conversion modules 116. Asshown in FIG. 6, there is also an IF distribution network 124 fordelivering the IF transmit signal to each of the up-conversion modules102. And as shown in FIG. 7, there is an IF aggregation network 126 foraggregating the received signals from each of the down-conversionmodules 116.

The distribution and aggregation networks may be passive linearreciprocal networks with electrically identical paths to ensure thecoherent distribution/aggregation of signals. Alternatively, one or moreof these networks may be implemented using the bidirectional signalingnetwork described in U.S. Pat. No. 8,259,884, entitled “Method andSystem for Multi-Point Signal Generation with Phase Synchronized LocalCarriers,” filed Jul. 21, 2008 and U.S. Pat. No. 8,611,959, entitled“Low Cost, Active Antenna Arrays,” filed Jun. 30, 2011 or the serialinterconnection approach described in U.S. Ser. No. 15/259,639, entitled“Calibrating a Serial Interconnection,” filed Sep. 8, 2016, the contentsof all of which are incorporated herein by reference.

Each up-conversion module 102 includes a mixer 103 and various amplitudeand phase setting circuits identified by A and P, respectively. The LOsignal and the distributed IF transmit signal stream are both providedto the mixer 103 which up-converts the IF transmit signal stream to anRF transmit signal stream that is provided to the power amplifier 106.Similarly, each down-conversion module 116 also includes a mixer 117 andvarious amplitude and phase setting circuits similarly identified by Aand P, respectively. The mixer 117 in the down-conversion module 116multiplies the LO signal provided by the LO distribution network 120 andthe received RF signal stream from the low noise amplifier 112 that iscoupled to the antenna element 110 a to generate a down-converted IFreceived signal stream. The down-converted IF signal stream is providedto the IF aggregation network 126 for aggregation with the IF receivedsignal streams from the other antenna elements and for delivery back tothe base station.

The amplitude and phase setting circuits A and P are used for changingthe relative phase or amplitude of individual antenna signals to therebyestablish the size, direction, and intensity of the transmit and receivebeam patterns that are generated by the antenna array. (Note: In anantenna array, a transmit beam is a radiation pattern that is generatedby the antenna array. That radiation pattern can be measured in front ofthe antenna array. In contrast, a receive beam is not a radiationpattern formed by the antenna array but rather is a pattern of antennasensitivity. Nevertheless, in spite of this difference, they are bothgenerally referred to as beams.) The amplitude setting circuit isbasically equivalent to a variable gain amplifier, in which the ratio ofthe output signal amplitude to the input signal amplitude isprogrammable and is set by electronic control. The phase setting circuithas the fundamental capability of shifting the input signal in phase (ortime) under electronic control. These amplitude and phase settingcircuits are controlled by digital control signals supplied by aseparate control processor 113.

The typology of the amplitude setting and phase setting circuits shownin FIGS. 6 and 7 is just one of many possibilities for giving the basictransmitter and receiver the capability to control independently theamplitude and phase values of the individual antenna signals. The numberand placement of the amplitude and phase setting circuits can vary fromwhat is illustrated in FIGS. 6 and 7 and depends on the implementationapproach that is employed. In addition, there are other components whichmight be present in the up-conversion and down-conversion modules butwhich are not shown in the figures because they are well known topersons skilled in the art. These might include, for example, channel IFfilters and automatic gain controls.

Other embodiments are within the scope of the following claims. Forexample, poor return loss may also be detectable through an arraycalibration process, such as is described in U.S. Ser. No. 62/216,592,filed Sep. 10, 2015, entitled “Methods for Active Array Calibration,”and incorporated herein by reference in its entirety. In other words, itis possible that some problems with the radiating elements and theconnections thereto can also be detected by simply examining the rangesof phase and gain within the calibration data for the array. In thatcase, the testing of calibration data can be combined with the crosselement gain measurement tests to perform a complete test of the array.

The RF power detector circuitry mentioned above is standard RF circuitryof which there are many different types available. Though it should beunderstood that the return loss measurement can be performed in waysother than by using an RF power detector. For example, one could use atime delay reflectometer (TDR), which is basically just another circuitimplementation for measuring return loss (or VSWR).

If CW tones are used, then the elements being tested need to be takenout of service. If DSSS (direct sequence spread spectrum) is used, theelements can be tested while in operation because the signal level ofthe DSSS signal can be extremely small to the spread spectrum recoveryprocessing gain.

If the system is FDD (Frequency Division Duplex), then the Tx returnloss and Tx cross element gain test can be done at a frequency in the Txband and the Rx return loss can be done using a frequency in the Rxband, though that may not be necessary. If the system is TDD (TimeDivision Duplex), the Tx and Rx bands are the same, so using onefrequency would suffice.

What is claimed is:
 1. A method of testing a phased array antenna thatincludes a plurality of antenna element pairs, each antenna element pairof the plurality of antenna element pairs including a first antennaelement and a second antenna element, said method comprising: for eachantenna element pair of the plurality of antenna element pairs,performing a first cross element gain measurement from the first antennaelement to the second antenna element of that antenna element pair; anddetermining whether there is a problem associated with the phased arrayantenna by examining the first cross element gain measurements for theplurality of antenna element pairs.
 2. The method of claim 1, furthercomprising: for each antenna element pair of the plurality of antennaelement pairs, performing a second cross element gain measurement fromthe second antenna element to the first antenna element of that antennaelement pair, wherein determining whether there is a problem associatedwith the phased array antenna also involves examining the second crosselement gain measurements for the plurality of antenna element pairs. 3.The method of claim 2, wherein determining whether there is a problemassociated with the phased array antenna also involves, for each antennaelement pair among the plurality of antenna element pairs, comparing thefirst and second cross element gain measurements for that antennaelement pair.
 4. The method of claim 2, further comprising: for eachantenna element pair of the plurality of antenna element pairs,performing a first return loss measurement for the first antenna elementof that antenna element pair and performing a second return lossmeasurement for the second antenna element of that antenna element pair,wherein determining whether there is a problem associated with thephased array antenna also involves examining the first and second returnloss measurements for the plurality of antenna element pairs.
 5. Themethod of claim 2, wherein, for each antenna element pair of theplurality of antenna element pairs, performing the first cross elementgain measurement from the first antenna element to the second antennaelement of that antenna element pair comprises measuring the power of asignal sent to the first antenna element of that antenna element pairand measuring the power received by the second antenna element of thatantenna element pair.
 6. The method of claim 2, wherein within eachantenna element pair among the plurality of antenna element pairs thefirst and second antenna elements of that pair are orthogonally orientedwith respect to each other.
 7. The method of claim 6, wherein withineach antenna element pair among the plurality of antenna element pairsthe first and second antenna elements of that pair are cross-polarized(±45°) pairs.
 8. The method of claim 6, wherein within each antennaelement pair among the plurality of antenna element pairs the first andsecond antenna elements of that pair are H—V polarized pairs.
 9. Anapparatus system comprising: a phased array antenna comprising an arrayof antenna elements, the array of antenna elements forming a pluralityof antenna element pairs, each antenna element pair of the plurality ofantenna element pairs including a first antenna element and a secondantenna element; a plurality of transmitter circuits, each transmittercircuit of the plurality of transmitter circuits connected to adifferent corresponding one of the antenna elements within the array ofantenna elements; for each transmitter circuit among the plurality oftransmitter circuits, a bidirectional coupler connected between thattransmitter circuit and the antenna element to which that transmittercircuit is connected; a detector system for measuring a signalcharacteristic; a switching system for selectively connecting signalsfrom the bidirectional couplers for the plurality of transmittercircuits to the detector system; and a processor system programmed touse the switching system and the detector system to perform theoperations of: for each antenna element pair of the plurality of antennaelement pairs, performing a first cross element gain measurement fromthe first antenna element to the second antenna element of that antennaelement pair; and determining whether there is a problem associated withthe phased array antenna by examining the first cross element gainmeasurements for the plurality of antenna element pairs.
 10. Theapparatus of claim 9, wherein the processor system is further programmedto use the switching system and the detector system to perform theoperations of: for each antenna element pair of the plurality of antennaelement pairs, performing a second cross element gain measurement fromthe second antenna element to the first antenna element of that antennaelement pair; and determining whether there is a problem associated withthe phased array antenna by also examining the second cross element gainmeasurements for the plurality of antenna element pairs.
 11. Theapparatus of claim 10, wherein the processor system is furtherprogrammed to determine whether there is a problem associated with thephased array antenna by also, for each antenna element pair among theplurality of antenna element pairs, comparing the first and second crosselement gain measurements for that antenna element pair.
 12. Theapparatus of claim 10, wherein the processor system is furtherprogrammed to use the switching system and the detector system toperform the operations of: for each antenna element pair of theplurality of antenna element pairs, performing a first return lossmeasurement for the first antenna element of that antenna element pairand performing a second return loss measurement for the second antennaelement of that antenna element pair, and determining whether there is aproblem associated with the phased array antenna by also examining thefirst and second return loss measurements for the plurality of antennaelement pairs.
 13. The apparatus of claim 9, wherein within each antennaelement pair among the plurality of antenna element pairs, the first andsecond antenna elements of that pair are orthogonally oriented withrespect to each other.
 14. The apparatus of claim 13, wherein withineach antenna element pair among the plurality of antenna element pairs,the first and second antenna elements of that pair form across-polarized)(±45°) pair.
 15. The apparatus of claim 13, whereinwithin each antenna element pair among the plurality of antenna elementpairs, the first and second antenna elements of that pair form a H—Vpolarized pair.
 16. The apparatus of claim 10, further comprising: an RFpilot signal source; for each transmitter circuit among the plurality oftransmitter circuits, a directional coupler connected to supply a signalto that transmitter circuit; and a second switching system forselectively connecting signals from the RF pilot signal source to thedirectional couplers for the plurality of transmitter circuits, andwherein the processor system is further programmed to also use the RFpilot signal source and the second switching system to perform theoperations of: for each antenna element pair of the plurality of antennaelement pairs, performing the first cross element gain measurement fromthe first antenna element to the second antenna element of that antennaelement pair and performing the second cross element gain measurementfrom the second antenna element to the first antenna element of thatantenna element pair.
 17. The apparatus of claim 16, wherein theprocessor system is further programmed to also use the RF pilot signalsource and the second switching system to perform the operations of: foreach antenna element pair of the plurality of antenna element pairs,performing a first return loss measurement for the first antenna elementof that antenna element pair and performing a second return lossmeasurement for the second antenna element of that antenna element pair.